DE102009042520A1 - Method for operating a coke oven arrangement - Google Patents

Abstract

The invention relates to a method for operating a coke oven arrangement, wherein the coke oven gas occurring in the coking process is supplied as useful gas to a material utilization. According to the invention, at least part of the thermal energy required for the coking process is supplied as fuel gas to a synthesis gas, which is produced by means of a gasification process from a fossil fuel, preferably coal.

Description

The invention relates to a method for operating a coke oven arrangement, wherein the coke oven gas occurring in the coking process is supplied as useful gas to a material utilization.

In practice, the coke oven gas obtained in a coking process is usually burned and thus only used energetically, although coke oven gas contains large amounts of the valuable components hydrogen and methane. Reservations against use result from the fact that coke oven gas is no longer available as fuel gas in case of material use and the lack of heating energy has to be provided elsewhere.

From the DE 34 244 24 A1 a method is known in which the resulting in the coking process coke oven gas is supplied as a useful gas material recycling. In the process, hydrogen is separated off and a suitable H ₂ -CO ratio is set in order subsequently to produce a synthetic natural gas by methanation. Since coke oven gas is no longer available for producing the thermal energy required for the coking process in the case of material utilization, blast furnace gas or mine gas is proposed as replacement gas for the underfiring of the coke oven gas battery. The use of gout or mine gas is an option if there is a steel mill or coal mine in the immediate vicinity of the coking plant and the use of these substitute gases turns out to be economical. Since these specifications are seldom met in practice, as described above, usually only one utilization of coke oven gas for heating purposes.

Other methods in which Koksofengas is fed to a material use, are from the DE 35 15 250 A1 as well as the DE 38 05 397 A1 known. In these methods, it is provided in each case that the coke oven gas having a high hydrogen content is mixed with the high carbon monoxide-containing metallurgical gas. The known methods assume that metallurgical gas, which must first be laboriously cleaned, is available to a sufficient extent.

The present invention has for its object to allow for the operation of a coke oven assembly, a flexible and efficient use of the resulting Koksofengases.

The object of the invention and solution of the problem is a method for operating a coke oven arrangement with the features described above, which is characterized in that for providing at least a portion of the required for the coking process thermal energy as fuel gas, a synthesis gas is supplied, which by means of a gasification process fossil fuel is generated. The use of a fossil fuel to produce the synthesis gas results in a particularly high flexibility of the method for operating a coke oven arrangement. Although the provision of the fossil fuel and the implementation of the gasification process for the production of synthesis gas are associated with additional investment and process costs, resulting in the recovery of the recyclable components contained in the Koksofengas total economic benefits. This is particularly the case when coal is used as the fossil fuel, which is comparatively cheap compared to other fossil fuels suitable for carrying out the gasification process, such as natural gas, and which is already provided for the implementation of the coking process. The inventive method can thus be used independently of other production cities such as coal mines or blast furnaces. However, if a blast furnace system is provided in the immediate vicinity, it is also possible to supply an additional portion of the generated synthesis gas for thermal utilization to a blast furnace.

According to the invention, it is proposed to separate off the gas components resulting from the coke oven process in the coke oven gas, such as hydrogen and / or methane, and to use them either as end products or convert them into even higher-value products, in which case the amount of energy missing from the coking process and possibly even a blast furnace process is lost by means of gasification from the fossil fuel produced synthesis gas is replaced. The raw synthesis gas produced usually only needs to be desulphurized before it is supplied as a fuel gas to provide a portion of the thermal energy required for the coking process and used in particular for undercutting coke oven batteries. An elaborate treatment of the synthesis gas, which includes, inter alia, the removal of carbon dioxide, is not required in the synthesis gas used as fuel gas.

In the context of the invention can be provided to use the synthesis gas formed from the fossil fuel exclusively for the provision of thermal energy as fuel gas. According to a preferred embodiment of the invention, however, more synthesis gas is generated than is necessary for the replacement of the inventively recycled Koksofengases. Thus, it can be provided that a first portion of the synthesis gas generated is used as the fuel gas and that an additional portion of the synthesis gas generated for a further conversion and material use is used.

In the context of the process according to the invention, the coke oven gas obtained in the coking process is first freed in a manner known per se from impurities such as tar, naphthalene, aromatic hydrocarbons (BTX components), sulfur and ammonia, as in the prior art in a conventional coking process is provided. According to a preferred embodiment of the invention, the previously purified coke oven gas for the separation of hydrogen and / or hydrocarbons is compressed. For the separation of the hydrogen, for example, a pressure swing adsorption (PSA) can be provided in a PSA plant, wherein the hydrogen is recovered on the pressure side of the PSA plant in highly pure form. The pressure swing absorption can be carried out both in a conventional PSA plant or a vacuum PSA plant (VPSA plant).

On the expansion side of the PSA plant, a methane-rich gas is recovered, which is separated in further treatment steps of the remaining gas components, in particular carbon monoxide (CO), carbon dioxide (CO ₂ ), nitrogen, acetylene and hydrogen still containing. The removal of nitrogen, carbon monoxide and hydrogen still contained can be carried out for example by a cryogenic distillation, with previously carbon dioxide and steam with suitable methods, eg. B. by means of an Armin wash and / or a molecular sieve drying are to be removed. The hydrocarbon components thus obtained as useful gas can be supplied to a natural gas network and / or kept ready for further synthesis.

As already described, the gas components obtained from the Kokereigas can be used as end products or converted into even higher quality products, for further synthesis and conversion and a proportion of the synthesis gas formed in the gasification of the fossil fuel can be used. Advantageous possibilities of use are explained below.

The separated hydrogen can generally be used as hydrogenating hydrogen in adjacent chemical plants, for example refineries. According to a preferred embodiment, it is provided to subject the hydrogen produced and a portion of the synthesis gas formed by the gasification of the fossil fuel to further conversion, the hydrogen being reacted with a portion of the carbon monoxide of the synthesis gas to give higher-value products. Thus, for example, a synthesis of methanol and beyond the production of fuel by an MTG process (methanol to gasoline), the synthesis of diesel by a Fischer-Tropsch process or the synthesis of ammonia can be provided.

If the use of the recovered hydrogen with the synthesis gas obtained from the fossil fuel, which essentially comprises carbon monoxide, is provided for a further synthesis, there is the advantage that a specific hydrogen / carbon monoxide ratio is released by a corresponding inflow control in a wide range can be chosen.

In particular, in order to further increase the hydrogen yield in relation to the entire process, provision can be made for a proportion of the synthesis gas produced to undergo CO conversion. For this purpose, the CO conversion can be carried out with the addition of water vapor, wherein after desulfurization of the converted synthesis gas carbon dioxide is at least partially removed, wherein subsequently the remaining gas stream is subjected to the removal of hydrogen pressure swing adsorption and wherein the resulting hydrogen-depleted Off- Gas is used as fuel gas for the coking process. Typically, this thermally recovered off-gas is a proportion of the total required to provide the thermal energy fuel gas.

As a further use of the synthesis gas formed from the fossil fuel and the generation of electricity with a combined gas and steam power plant (GUD process) may be provided.

According to the invention, part of the thermal energy required for the coking process is provided by a synthesis gas as fuel gas, which is obtained by means of a gasification process from the fossil fuel, preferably by coal gasification. In order to provide a further part of the thermal energy, the residual and exhaust gases produced in various subsequent process stages can also be used for combustion. In particular, the off-gas of the preferably provided PSA plant usually still contains large amounts of combustible components that can be thermally recycled by combustion. Furthermore, high-quality fuels with a higher calorific value, such as natural gas, can also be admixed. Such admixture may be required to set a desired Wobbe number or to balance an energy requirement not yet covered by the other fuel gases.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3424424 A1 [0003]
• DE 3515250 A1 [0004]
• DE 3805397 A1 [0004]

Claims (10)

A method for operating a coke oven arrangement, wherein the resulting coke oven in the coke oven gas coke oven gas is recycled, characterized in that for providing at least a portion of the required for the coking process thermal energy as fuel gas, a synthesis gas is supplied, which by means of a gasification process from a fossil fuel is generated. A method according to claim 1, characterized in that coal is used as the fossil fuel. A method according to claim 1 or 2, characterized in that the coke oven gas is compressed and desulfurized before hydrogen removed therefrom and subsequently hydrocarbons are separated from residual gas components. Method according to one of claims 1 to 3, characterized in that hydrogen is separated from the coke oven gas by pressure swing adsorption, wherein subsequently hydrocarbons are separated by means of a cryogenic distillation. Method according to one of claims 1 to 4, characterized in that a first portion of the synthesis gas generated is used as the fuel gas and that an additional portion of the synthesis gas generated is used for further synthesis with the hydrogen separated from the coke oven gas. Method according to one of claims 1 to 5, characterized in that a first portion of the generated synthesis gas is used as the fuel gas and that an additional portion of the synthesis gas generated is subjected to a CO conversion. A method according to claim 6, characterized in that the CO conversion takes place with the addition of water vapor, wherein after desulfurization of the converted synthesis gas carbon dioxide is at least partially removed, wherein subsequently the remaining gas stream is subjected to the removal of hydrogen pressure swing adsorption and wherein the thereby resulting to use hydrogen-depleted off-gas as fuel gas for the coking process. Method according to one of claims 1 to 7, characterized in that a first portion of the synthesis gas generated is used as the fuel gas and that an additional portion of the synthesis gas generated is used in a gas and steam power plant for power generation. Method according to one of claims 1 to 8, characterized in that in addition to the synthesis gas, a further heating gas is supplied to provide the thermal energy required for the coking process. Method according to one of claims 1 to 9, characterized in that an additional portion of the generated synthesis gas for thermal utilization is fed to a blast furnace.